静电聚焦同心球系统的成像电子光学 A章：电子轨迹方程

在成像电子光学中,静电聚焦同心球系统具有一系列宝贵的性质,其电位分布与电子轨迹能以解析形式表示,可以定量地研究系统的电子光学成像特性与横向像差。尽管前人已有不少研究,但都限于零级近似成像的认识,且其中存在着不少谬误。本系列文章将全面研究静电聚焦两电极与多电极同心球系统中电子的运动轨迹、电子光学成像特性与横向像差,探讨电子束在成像段形成的图像弥散,得出一些新的结论和认识,纠正文献中存在的一些谬误,建立自己的理论体系。本系列文章的第一篇主要探讨电子在两电极同心球系统中在静电场作用下的运动轨迹,导出了两电极静电聚焦同心球系统中自阴极面逸出的电子轨迹在极坐标系下的表示式ρ=f(φ)与圆柱坐标系下新的轨迹方程的表示式r=r(z),给出了自光阴极逸出的电子在成像段的行进轨迹的交轴位置及其斜率的近似和精确表示式。本文为全面研究静电聚焦同心球系统的电子光学性质及其像差奠定基础。     

复合电磁同心球系统的成像电子光学.A章:近轴光学

通过复合电磁同心球系统的理想模型,对成像电子光学近轴方程的轨迹求解进行探讨。首次推导了该系统的近轴电子轨迹的转角及近轴方程的两个特解的解析表达式,探讨了近轴成像性质,并将结果推广到两电极静电同心球系统、均匀平行复合电磁系统和静电近贴系统中。     

电磁聚焦同心球系统的电子光学

本文由电磁聚焦曲近轴方程出发,导出了电磁聚焦同心球系统的近轴轨迹的表达式,讨论了系统的聚焦性质与电子光学色球差,探讨了由电磁聚焦同心球系统向具有均匀平行的电场和磁场的电磁聚焦系统,静电聚焦同心球系统和近贴聚焦系统过渡的三种特殊情况,最后研究了加上栅网电极的三电极同心球静电聚焦系统和均匀平行的电场和磁场的三电极电磁聚焦系统的电子光学。     

两电极静电同心球系统的近轴电子光学及其空间-时间像差

将从近轴解出发研究两电极静电同心球系统的空-时轨迹及其像差.由近轴轨迹方程和近轴运动方程出发,先求解两电极静电同心球系统中自光阴极逸出的运动电子的近轴空间-时间轨迹,然后讨论此系统的静动态电子光学及其空间-时间像差,揭示近轴光学系统成像的一般规律.文中定义和推导了各级近轴空间像差和近轴时间像差,得到了与关于近轴空间-时间像差同样的结论,表明完全可以直接由近轴轨迹方程和近轴运动方程出发来研究理想成像及其空间-时间像差.     

静电聚焦同心球系统的成像电子光学 C章：多电极同心球系统的电子光学

鉴于两电极静电聚焦同心球系统成像的定焦性质,当该系统的几何尺寸相对关系给定后,像面位置与放大率也就随之确定,改变系统的电参量引起的像面位置和放大率的变动是极其微小的。研究在由光阴极与栅状阳极组成的两电极同心球系统中插入任意多个栅极后,该系统的电子光学成像特性及其横向像差的变化规律。再次证实了在多电极静电聚焦同心球系统中,成像电子光学系统的二级近轴横向色差即Recknagel-Apцимович公式依然成立。着重讨论了三电极静电聚焦同心球系统的电子光学成像特性。     

静电聚焦同心球系统的成像电子光学 B章：近轴横向色差与几何横向球差

在A章基础上,进一步研究两电极静电聚焦同心球系统的轴上点电子光学横向像差。研究表明,对于成像电子光学系统,由光阴极发射的电子所形成的图像弥散,其轴上点的图像弥散由近轴横向色差与几何横向球差两部分组成,这证明了在静电聚焦同心球系统中,阴极透镜的二级近轴横向色差即Recknagel-Apцимович公式普遍成立。研究了宽电子束与细电子束之间轴上点横向像差之差异,最后讨论了两电极同心球系统向近贴聚焦系统过渡的特例。     

两电极静电同心球系统的成像电子光学及其空间-时间像差

基于实际轨迹方程和电子运动方程对两电极静电同心球系统求解由光阴极逸出的运动电子的空间和时间轨迹,推导成像位置和电子飞行时间的精确和近似表达式,并由空间和时间轨迹的解析解出发讨论系统的空间-时间特性.对空间像差和时间像差给出统一的定义,即横向像差可视为近轴横向像差和几何横向像差的合成,时间像差可视为近轴时间像差和几何时间像差的合成,并导出了所有相应的像差表示式.     

静电聚焦同心球系统验证电子光学成像系统的时间像差理论

关于动态电子光学成像系统的时间像差理论,计算时间像差系数有两种方法——τ变分法和直接积分法.它们的差别在于：τ变分法计算二级几何时间像差系数必须求解微分方程,而直接积分法仅需进行积分运算.采用静电同心球系统的理想模型对这两种方法的正确 性进行了检验.结果表明：这两种方法求解电子光学成像系统的时间像差系数的结果完全一致,所求得的时间色差系数与理想模型的解析解完全相同,从而证明两种方法是等价并且正确的.通过验证表明,直接积分法的计算更为简便,适于实际系统的计算与设计. 关键词： 阴极透镜 电子光学成像系统 动态电子光学 时间像差理论     

复合电磁同心球系统的成像电子光学. D章:近轴方程渐近解（英文）

首次探讨了复合电磁同心球系统近轴方程的渐近解。推导了复合电磁同心球系统中近轴方程两个特解的渐近解中各类系数的表达式。通过复合电磁同心球系统两个特解精确解的验证,证明了Monastyrski[Journal of Technical Physics,1978,48(6):1117-1122]提出的用渐近解求解成像电子光学近轴方程两个特解的方法正确且可行,仅个别之处需要改进。     

复合电磁同心球系统的成像电子光学.B章:近轴像差

由复合电磁同心球系统的近轴方程两个特解出发,通过展开理想成像位置处图像转角表达式的途径,探讨了复合电磁同心球系统的近轴纵向像差和近轴横向像差。主要贡献是求得了近轴方程的两个特解在理想像面位置处的解析表达式,由此证明决定极限空间分辨率的二级近轴色球差能以Recknagel-Artimovich公式描述。导出了近轴横向像差的表达式,该像差由近轴色球差、近轴放大率色差和近轴各向异性色差等组成。     

A new bifurcation in non-smooth continuous system inducing semi-limit cycle

In this paper, we presented a study on a non-smooth continuous system with emphasis on a special bifurcation. As the parameter varies, a series of concentric closed orbits appear near the equilibrium point. Moreover, the outermost closed orbit attracts all the trajectories outside. It is called as a semi-limit cycle as the trajectories at only one side of this orbit are attracted. By using the theory of generalized Jacobian matrix, it is revealed that this bifurcation can be featured by a pair of complex conjugate eigenvalues reaching exactly but not crossing the imaginary axis. The bifurcation can somewhat be considered to be a degenerate case of the Hopf bifurcation, in which the eigenvalues cross the imaginary axis totally. This study enriches the knowledge of bifurcation analysis for non-smooth dynamical systems.     

Ultrasonic backscatter coefficient quantitative estimates from Chinese hamster ovary cell pellet biophantoms

A cell pellet biophantom technique is introduced, and applied to the ultrasonic backscatter coefficient (BSC) estimate using Chinese hamster ovary (CHO) cells. Also introduced is a concentric sphere scattering model because of its geometrical similarities to cells with a nucleus. BSC comparisons were made between the concentric sphere model and other well-understood models for mathematical verification purposes. BSC estimates from CHO cell pellet biophantoms of known number density were performed with 40 and 80 MHz focused transducers (overall bandwidth: 26-105 MHz). These biophantoms were histologically processed and then evaluated for cell viability. Cell pellet BSC estimates were in agreement with the concentric sphere model. Fitting the model to the BSC data yielded quantitative values for the outer sphere and inner sphere. The radius of the cell model was 6.8 ± 0.7 μm; the impedance of the cytoplasm model was 1.63 ± 0.03 Mrayl and the impedance of the nuclear model was 1.55 ± 0.09 Mrayl. The concentric sphere model appears as a new tool for providing quantitative information on cell structures and will tend to have a fundamental role in the classification of biological tissues.     

Natural curvilinear coordinates for ideal MHD equations. Non-stationary flows with constant total pressure

Equations of magnetohydrodynamics (MHD) in the natural curvilinear system of coordinates where trajectories and magnetic lines play a role of coordinate curves are reduced to the non-linear vector wave equation coupled with the incompressibility condition in the form of the generalized Cauchy integral. The symmetry group of obtained equation, equivalence transformation, and group classification with respect to the constitutive equation are calculated. New exact solutions with functional arbitrariness describing non-stationary incompressible flows with constant total pressure are given by explicit formulae. The corresponding magnetic surfaces have the shape of deformed nested cylinders, tori, or knotted tubes.     

Sound scattering from two concentric fluid spheres (L)

The solution to the problem of plane wave and point source scattering by two concentric fluid spheres is derived. The effect of differences in sound speed, density, and absorption coefficient is taken into account. The scattered field is then found in the limit as the outer sphere becomes an infinitely thin shell and compared to the solution for a single fluid sphere for verification. A simulation is then performed using the concentric fluid sphere solution as an approximation to the human head and compared to the solution of a single fluid sphere with the properties of either bone or water. The solutions were found to be similar outside of the spheres but differ significantly inside the spheres.     

Majorana stellar representation for mixed-spin (s, 1/2) systems

By describing the evolution of a quantum state with the trajectories of the Majorana stars on a Bloch sphere,Majorana’s stellar representation provides an intuitive geometric perspective to comprehend the quantum system with highdimensional Hilbert space.However,the representation of a two-spin coupling system on a Bloch sphere has not been solved satisfactorily yet.Here,a practical method is presented to resolve the problem for the mixed-spin(s,1/2)system and describe the entanglement of the system.The system can be decomposed into two spins:spin-(s+1/2)and spin-(s?1/2)at the coupling bases,which can be regarded as independent spins.Besides,any pure state may be written as a superposition of two orthonormal states with one spin-(s+1/2)state and the other spin-(s?1/2)state.Thus,the whole initial state can be regarded as a state of a pseudo spin-1/2.In this way,the mixed spin decomposes into three spins.Therefore,the state can be represented by(2s+1)+(2s?1)+1=4s+1 sets of stars on a Bloch sphere.Finally,some examples are given to show symmetric patterns on the Bloch sphere and unveil the properties of the high-spin system by analyzing the trajectories of the Majorana stars on the Bloch sphere.     

大视场红外同心光学系统的设计

研究了同心光学系统的成像特性以及设计方法,分析了厚透镜的成像理论。设计了工作在3．7～4．8μm、视场15°的红外同心光学系统,该系统具有接近衍射极限的成像质量。对红外同心光学系统各个视场的传递函数进行了测试,结果表明该系统具有较好的成像质量,且成像特性和同心光学系统的成像原理是一致的。     

Static and dynamic imaging electron optics and spatial-temporal aberrations in a bi-electrode spherical concentric system with electrostatic focusing

In imaging electron optics, for a concentric spherical system composed of two spherical electrodes with electrostatic focusing, the electrostatic potential distribution and the spatial-temporal trajectory of electron motion can be expressed by analytical forms. It is naturally to take such system as an ideal model to investigate the imaging properties, as well as the spatial-temporal aberrations, to analyze its particularity and to find the clue of universalities and regularities. Research on this problem has important significance, which can afford theoretical foundation not only in studying static electron optics for the night vision devices, but also in studying dynamic electron optics for high-speed image converter tubes.In the present paper, based on the practical electron ray equation and electron motion equation for a bi-electrode concentric spherical system with electrostatic focusing, the spatial-temporal trajectories of moving electrons emitted from the photocathode have been solved, the exact and approximate formulae for image position and flight time of electrons, have been deduced. Start from solutions of spatial-temporal trajectories, the electron optical spatial-temporal properties of this system are then discussed. According to the definitions of spatial-temporal aberrations, the paraxial and geometrical lateral aberrations, as well as the paraxial and geometrical temporal aberrations, have been deduced, that are classified by the order of and .     

A reconstruction in Minkowskian space-time of Einstein's assembly of test particles

We construct the energy-momentum tensor in Minkowskian space-time for Einstein's collisionless system of test particles moving in concentric circles and obtain the four-force necessary to preserve equilibrium. We derive a tensor field, satisfying the linearized Einstein equations, which is consistent with the applied four-force. If the particles are contained within a sphere, then outside the sphere we show that the tensor field is a linearized Schwarzschild fieldwith a cosmological constant (this constant being the potential energy calculated on the surface of the sphere).